JPS648530B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an uninterruptible power supply comprising a commercial power source and an inverter power source.

FIG. 1 shows the configuration of a conventional uninterruptible power supply of this type. In the figure, 1 is a commercial power supply, 2 is an inverter power supply that converts DC voltage into AC voltage, 3 is an AC filter circuit that bypasses and smooths the harmonics of the AC voltage supplied from the inverter power supply 2 via the line 4, 5 is a synchronization detection circuit for synchronizing the voltage of the inverter power supply 2 with the voltage of the commercial power supply 1; 6 is a commercial side switch using a semiconductor for turning on and off the commercial voltage; and 7 is a semiconductor for turning on and off the inverter voltage. The used inverter side switch 8' is a switching circuit that switches both switches 6 and 7 in an interlock state, and 9 outputs a switching command signal to select either the commercial power supply 1 or the inverter power supply 2 to activate the switching circuit 8'. This is a switching command unit that controls the switching. This switching command unit 9 is supplied with the operating status of each part via a line 90, a switching command signal for switching from the commercial power supply 1 to the inverter power supply 2 is outputted from a line 91, and a switching command signal for switching from the commercial power supply 1 to the inverter power supply 2 is outputted from a line 92. A switching command signal is issued to switch to. 10, either the commercial voltage or the inverter voltage is connected to the switch 6,
7 and the load is switched over and supplied via a common output line 11, I ₁ is an ammeter that measures the current on line 4 via current transformer CT ₁ , I 2 is an ammeter that measures the current on line 4 via current transformer CT 2, and I ₂ is connected to line 1 via current transformer CT ₂ .
1 is an ammeter that measures the current, and V is a voltmeter that measures the voltage of the line 11.

In such an uninterruptible power supply, the inverter power supply 2 is always operated in synchronization with the commercial power supply 1, so the voltage phases of the commercial power supply 1 and the inverter power supply 2 match. In this state, high-quality power is always supplied to the load from the inverter power supply 2, but
When the load 10 becomes overloaded transiently, the inverter power supply 2 instantly switches to the commercial power supply 1, and power is supplied from the commercial power supply 1 to the load 10. When the load 10 recovers from the transient load and reaches the rated load state, the commercial power supply 1 to inverter power supply 2.

However, in conventional uninterruptible power supplies, when switching from a commercial power source 1 with a large capacity to an inverter power source 2 with a small capacity, this is done at any point in one cycle of the AC voltage, so each time there is a change in the instantaneous voltage. They vary in size, with larger ones about 20
The drawback was that a voltage that was 30% lower was supplied to the load 10. If such an undervoltage is supplied to a load 10 such as an electronic computer, there is a risk that it may cause an accident in the load 10.

An object of the present invention is to provide an uninterruptible power supply device that can suppress instantaneous voltage fluctuations as much as possible when switching from a commercial power source to an inverter power source.

In the present invention, as shown in Fig. 2A and B, there is a gap between the output voltage V of the commercial power supply and the inverter power supply that are operated synchronously, and the inverter output current _I1 in the no-load state before passing through the AC filter circuit. Focusing on the fact that there is always a constant phase relationship, when switching from a commercial power source to a smaller capacity inverter power source,
By issuing a switching trigger signal at a certain phase shift from the output voltage, switching is performed at or near the zero point of the inverter output current before passing through the AC filter circuit (each t ₁ section in Figure 2 B), and when switching The first feature is to suppress fluctuations in instantaneous voltage. In the figure, _t2 is the range in which switching from commercial power supply to inverter power supply is not performed, and T is the period.

The second feature of the present invention is that when switching from a commercial power source to an inverter power source, the output voltage of the inverter power source is increased before switching to further suppress instantaneous voltage fluctuations at the time of switching. There is.

Hereinafter, specific examples of the present invention will be described in detail with reference to the drawings. FIG. 3 shows an embodiment of the uninterruptible power supply according to the present invention. Note that the same parts as in FIG. 1 are given the same reference numerals, and their explanation will be omitted. In the figure, 12 is a voltage that detects the output voltage of the commercial power supply 1 or the output voltage of the inverter power supply 2 and outputs a switching trigger signal at a phase corresponding to the zero point or the vicinity of the zero point of the inverter output current before passing it through the AC filter circuit 3. This is a detection type trigger circuit. In this embodiment, the output voltage of the AC filter circuit 3 is detected. Reference numeral 13 denotes a voltage compensation command unit that performs control to increase the output of the inverter power supply 2 in advance according to the load current when switching from the commercial power supply 1 to the inverter power supply 2, and the control circuit 14
and a voltage compensation command main circuit 15.
When the switching command signal for switching from the commercial power supply 1 to the inverter power supply 2 is output from the line 91 of the switching command section 9, the control circuit 14 immediately issues a compensation start command to the voltage compensation command main circuit 15 and switches until the voltage compensation is completed. The command signal is delayed, and when voltage compensation is completed, a switching command signal is given to the switching circuit 8, and a compensation termination command is issued to the voltage compensation command main circuit 15. Voltage compensation command main circuit 1
Reference numeral 5 monitors the load current, and when a compensation start command is issued from the control circuit 14, it outputs a voltage compensation command signal proportional to the load current. 8 inputs a switching command signal given directly from the switching command section 9 or via the voltage compensation command section 13 and a switching trigger signal from the voltage detection type trigger circuit 12, and switches either the commercial side switch 6 or the inverter side switch 7. This is a switching circuit that outputs a switching signal to one side or the other. 1
6 is an inverter voltage control circuit, and this circuit is normally connected to the AC filter circuit 3 via line 17.
It monitors the output voltage of the inverter power supply 2 and controls it to maintain the output voltage of the inverter power supply 2 at a predetermined value.
When switching from the commercial power source 1 to the inverter power source 2, the inverter output voltage is controlled to be increased by a voltage compensation command signal given from the voltage compensation command section 13 through the line 18.

Such an uninterruptible power supply device connects the commercial power supply 1 to the inverter power supply 2 via the line 91 of the switching command unit 9.
When a switching command signal is issued, this signal is given to the voltage compensation command unit 13, and immediately a voltage compensation command signal is issued to the inverter voltage control circuit 16 to increase the inverter output by, for example, 5 to 10% in proportion to the load current. The output voltage of the inverter power supply 2 is increased by 5 to 10%. When the output voltage of the inverter power supply 2 rises in accordance with the load current, the commercial power supply 1 that has been stopped during that time
A switching command signal from the voltage compensation command section 13 to the inverter power supply 2 is given to the switching circuit 8 from the voltage compensation command section 13 . When a switching trigger signal is output from the voltage detection type trigger circuit 12 in such a state, a switching signal from the commercial power source 1 to the inverter power source 2 is instantly output from the switching circuit 8 to the commercial side switch 6 and the inverter side switch 7, and the switch is activated. 6 is turned off, switch 7 is turned on, and power is supplied to load 10 from inverter power supply 2.

This switching is performed at or near the zero point of the inverter output current before it passes through the AC filter circuit 3 in addition to compensating the inverter output voltage before switching, so when switching from a no-load state to a full-load state, Instantaneous voltage fluctuations can be suppressed as much as possible.

Note that when switching from inverter power supply 2 to commercial power supply 1, the above-mentioned considerations were not taken and line 9
Immediately upon receiving the switching command signal from 2.
Even if the switching is performed in this manner, since the commercial power supply 1 has a large capacity, the fluctuation in the instantaneous voltage at the time of switching is small and does not pose a problem.

FIG. 4 shows an example of a specific circuit configuration of the voltage detection type trigger circuit 12. In the figure, R ₁ to _{R 5} are resistors, C ₁ to _{C 4} are capacitors, and T ₁
is an isolation transformer that insulates the input AC voltage and outputs the AC voltage, and IC ₁ amplifies the DC voltage divided by resistors R ₁ and R ₂ to form the DC voltage for determining the trigger phase. The amplification integrated circuit IC ₂ is an isolation transformer that receives as input the DC voltage for trigger phase determination output from the amplification integrated circuit IC ₁ and the AC voltage obtained by shifting the phase of the AC voltage output from the isolation transformer T ₁ .
Phase control that outputs a switching trigger signal (pulse voltage) at a predetermined phase with respect to the output AC voltage of T ₁ (at a phase corresponding to the zero point of the inverter output current before passing through the AC filter circuit 3 or its vicinity) For the integrated circuit, V is the input alternating voltage of the isolation transformer _T1 .

5A, B, C, and D show waveforms of various parts of this voltage detection type trigger circuit 12.

The voltage detection type trigger circuit 12 is an isolation transformer to which an AC voltage V is input as shown in FIG. 5A.
The phase of the output AC voltage of T ₁ is shifted by θ using resistors R ₃ and R ₄ and capacitors C ₁ and C ₂ , and the phase-shifted AC voltage a as shown in FIG. 5B is transferred to a phase control integrated circuit IC _2. is input to generate a sawtooth voltage c as shown in FIG. 5C across capacitor _C4 . On the other hand, the DC voltage is divided by resistors R ₁ and R ₂ to create an amplification integrated circuit.
IC ₁ is applied to obtain a DC voltage b for determining the trigger phase as shown in FIG. 5C. The trigger phase determining DC voltage b and the sawtooth voltage c are matched by a phase control integrated circuit IC ₂ , and a predetermined voltage is applied to the AC voltage V as shown in FIG. 5D from the output terminal of this integrated circuit IC ₂ . A pulse-like switching trigger signal d is generated at the phase (at the phase corresponding to the zero point of the inverter output current before passing through the AC filter circuit 3 or its vicinity).
is output and applied to the switching circuit 8.

Note that the input voltage of the voltage detection type trigger circuit 12 is not limited to that obtained from the location shown in FIG. It can be obtained from either.

FIG. 6 shows an example of a specific circuit configuration of the control circuit 14 and the voltage compensation command main circuit 15 in the voltage compensation command unit 13. Control circuit 14
are resistors R ₆ to _{R 12} , capacitors C ₅ to C ₇ , transistors T _r1 and T _r2 , relay RY, normally closed relay contact rc, Zener diode ZD ₁ , and comparator IC ₃ . , NAND logic circuits _IC4 to _IC6 . The voltage compensation command main circuit 15 includes a resistor
_R13 , _R14 , capacitor _C8 , diode _Rf1 ,
It is composed of.

FIGS. 7A to 7F show waveforms of each part of the control circuit 14 and the voltage compensation command main circuit 15.
When the control circuit 14 receives a switching command signal A as shown in FIG. 7A from the switching command unit 9, the transistor T _r1 becomes conductive, and the charge in the capacitor C ₆ is discharged through the transistor T _r1 . In the comparator IC ₃ , the voltages at the voltage dividing points P ₁ and P ₂ are compared, and during the charging period T ₁ of the capacitor C ₆ , the output of the comparator IC ₃ is as shown in FIG. 7B. The level becomes high, which turns on the transistor T _r2 , energizes the relay RY, and turns off the normally closed relay contact rc.

When relay contact rc is turned off, this relay contact
The secondary output of current transformer CT ₂ , which was short-circuited by rc, is full-wave rectified by diode Rf ₁ and stored in capacitor C ₈ . The charge stored in the capacitor _C8 becomes a voltage compensation command signal 2 as shown in FIG. 7D and is applied to the inverter voltage control circuit 16 to increase the inverter output. If capacitor C ₆ is further charged after time T ₁ , then the capacitor
The charging voltage of C ₆ becomes larger than the voltage of Zener diode ZD ₁ , and the output of comparator IC ₃ becomes as shown in Fig. 7B.
It becomes a low level as shown in . When the output becomes low level, the NAND logic circuit IC ₄ ,
IC ₅ and IC ₆ operate, and the output voltage C of the NAND logic circuit IC ₆ becomes a low level as shown in FIG. 7C, and the switching command signal C is discharged for a time T ₂ determined by the time constants R ₁₂ and C ₇ . The signal is sent to the switching circuit 8 during the interval.

When the switching command signal C is output, the voltage compensation command signal D is attenuated by a time constant determined by the circuit constants C ₈ and R ₁₄ and the load impedance, as shown in FIG. 7D. In Fig. 7C, the switching command signal C is
When the switching trigger signal H of the voltage detection type trigger circuit 12 is given as shown in FIG. 7E while the voltage is on for a period of _T2 , the switching circuit 8 turns off the commercial side switch 6 and turns on the inverter side switch 7. Issue a switching signal.

As explained above, the uninterruptible power supply according to the present invention increases the output voltage of the inverter power supply immediately before switching from the commercial power supply to the inverter power supply.
It is possible to suppress instantaneous voltage fluctuations of the inverter power supply when switching to an inverter power supply with a smaller capacity. Moreover, in the present invention, the output voltage of the commercial power supply or the output voltage of the inverter power supply is detected and the switching trigger signal is output at a phase corresponding to the zero point of the inverter output current or its vicinity before passing it through the AC filter circuit, and Since switching to the inverter power source is performed, fluctuations in the instantaneous voltage of the inverter power source at the time of switching from the commercial power source to the small capacity inverter power source can also be suppressed as small as possible. In particular, in the present invention, the voltage detection type trigger circuit outputs a switching trigger signal at a predetermined phase with respect to the AC voltage (at a phase corresponding to the zero point of the inverter output current before passing through the AC filter circuit or its vicinity). , the switching timing does not fluctuate which occurs in the case of a type that issues a switching trigger signal at the peak of the AC voltage, and the commercial power supply can always be switched from the commercial power supply to the inverter power supply at or near the zero point of the inverter output current. , which has the advantage of improving the reliability of switching at desired times. According to experiments, the voltage fluctuation, which conventionally was about 20 to 30%, can be suppressed to about 2.5 to 5% according to the present invention. Therefore, according to the present invention, it is possible to provide a high-quality uninterruptible power supply, which is most suitable as a power supply for measurement and instrumentation of, for example, electronic computers and chemical plants. In addition, since the present invention uses a voltage detection method,
Since the detected voltage does not change significantly regardless of load variations, there is no need to provide special protection means for the voltage detection type trigger circuit, which is advantageous in practice.

[Brief explanation of drawings]

Figure 1 is a block diagram of a conventional uninterruptible power supply.
Figures 2A and B are waveform diagrams for explaining the principle of the present invention, Figure 3 is a block diagram showing an embodiment of the uninterruptible power supply according to the present invention, and Figure 4 is a voltage detection used in this device. A circuit diagram showing an example of a specific circuit configuration of a type trigger circuit, FIGS. 5A to D are waveform diagrams of each part in FIG. 4, and FIG. 6 is an example of a specific circuit configuration of a voltage compensation command section used in this device. Circuit diagram showing Figure 7A
-F are waveform diagrams of various parts in FIG. 1...Commercial power supply, 2...Inverter power supply, 3...
...Synchronization detection circuit, 6...Commercial side switch, 7...
Inverter side switch, 8...Switching circuit, 9...
Switching command unit, 12... Voltage detection type trigger circuit,
13... Voltage compensation command section, 14... Control circuit, 1
5... Voltage compensation command main circuit.

Claims (1)

[Claims] 1. In an uninterruptible power supply device that supplies power to a load without interruption by switching between a commercial power source and an inverter power source that are operated synchronously using a switching signal output from a switching circuit, the commercial power source and the inverter power source are a voltage detection type trigger circuit that detects the output voltage or the output voltage of the inverter power supply and outputs a switching trigger signal at a phase corresponding to the zero point or the vicinity of the zero point of the inverter output current before passing it through the AC filter circuit; a switching command section that outputs a switching command signal for selecting one of the inverter power sources; and a switching command section that delays the switching command signal when the switching command signal from the commercial power source to the inverter power source is given from the switching command section. a voltage compensation command section that issues a voltage compensation command signal to increase the inverter output voltage during that time, and issues the delayed switching command signal after the completion of the inverter voltage increase; and the voltage compensation command signal from the voltage compensation command section. an inverter voltage control circuit that performs control to increase the output voltage of the inverter power supply, and the switching circuit receives a switching command signal from the voltage compensation command unit and the voltage detection while the inverter output voltage is being compensated. An uninterruptible power supply device characterized in that the uninterruptible power supply device is configured to output a switching signal for switching from the commercial power source to the inverter power source when a switching trigger signal from a type trigger circuit matches.